Mass spectra of diterpene alkaloids with the hetisine skeleton

An analysis of literature material has shown that the stability of the M⁺ ions of bases with the hetisine skeleton decreases considerably when an OR group is present at C-1, C-6, or C-9. The directions of fragmentation are not monotypical and depend greatly on the positions of the oxygen substituents. A similar conclusion can be made from a study of the group and individual features of the breakdown of hetisine, nominine, talatisine, and their derivatives revealed with the aid of high-resolution mass spectrometry and MD spectra. An unusual property of these spectra is the formation of nitrogen-free fragments. The mass spectra of hetisine alkaloids of a new type — zeraconine and its N-oxide — have been characterized.     

Comparison of the secondary-ion and electron-impact mass spectra of alkaloids

An advantage of using secondary-ion spectra for determining the molecular masses of quaternary bases and bases the molecular ions of which are unstable to electron impact is shown. The LSIMS spectra of four groups of diterpene alkaloids include the 100% peaks of the (M + H)⁺ ions and the peaks of the main fragments present in the EI spectra. The B/E = const. spectra of the key ions obtained by the different methods are compared. The closeness of the values of A of analogous transitions calculated from the B/E and MD spectra is confirmed.     

Glycosylation of cardenolides. VIII. Structures of the by-products of the synthesis by the orthoester method of strophanthidol rhamnosides

The by-products formed in the preparation of strophanthiodol 19-rhamnoside and 3, 19-bisrhamnoside by the orthoester method are 3β,5-dihydroxy-8,19-epoxy-5β,14β, 17α-card-20(22)-enolide and its 3-α-L-rhamnoside. 3β,5-Dihydroxy-8,19-epoxy-5β, 14α,17β-card-20(22)-enolide has been obtained by the action of a solution of HBr in nitromethane on strophanthidol.     

A mass spectrometric study of substituted furfuryl compounds

The mass spectra of six furfuryl compounds — namely, furfuryl alcohol, 5-furfuryl-furfuryl alcohol, difurfuryl ether, difurylmethane, 2,5-difurfurylfuran, and 4-furfuryl-2-pentenoic acid-γ-lactone — have been studied. Their fragmentation mechanisms are discussed in detail with particular emphasis on the modes that lead to the formation of aromatic fragments. The majority of the fragment ions are formed by elimination of CO and C₂H₂ from even-electron precursor ions and HCO from odd-electron precursor ions. Molecules containing two furan rings linked by a methylene group give mass spectra that exhibit large abundances of aromatic fragment ions.     

Characterization of gem-difluoropropargyl synthons through HF loss from protonated molecules in methane chemical ionization mass spectra

Electron impact and methane chemical ionization mass spectra were obtained following gas chromatography/mass spectrometry for several gem-difluoropropargyl compounds, which had been synthesized as potential intermediates for synthesis of gem-difluoromethylene-containing C-3 acetylenes. EI spectra were variable with respect to the presentation of molecular ions, depending on substituent functional groups present. Methane-CI spectra were characterized by loss of 19 mass units from molecular weight with all compounds examined. These [M − 19]⁺ ions often presented as base peaks of the CI spectra, and were more reliably present and abundant than [M + 1]⁺ ions for these compounds. These ions could have been formed by elimination of HF from the protonated molecules under conditions of methane chemical ionization.     

Reduction of trinitroaromatic compounds in water by chemical ionization mass spectrometry

A reduction process was found to occur in the ion source when observing the chemical ionization mass spectra of a series of trinitroaromatic compounds, using water as reagent. The [MH–30]⁺ ions in the CI mass spectra were due mainly to the reduction of the compounds to their corresponding amines. This was proved by using D₂O as reagent: the [MH–30]⁺ ions were shifted to [MD–28]⁺ ions. The trinitroaromatic compounds investigated included 1,3,5-trinitrobenzene, 2,4,6-trinitrotoluene, 2,4,6-trinitro-m-cresol, 2,4,6-trinitroaniline (picramide) and 2,4,6-trinitrophenol (picric acid).     

B/E linked scanning spectra of the molecular and fragmentary ions of lycoctonine bases

The B/E linked scanning spectra of the M⁺, (M-15)⁺, and (M-OR₁)⁺ ions and those of some other series have been investigated. The characteristic nature of the individual intensities of the metastable peaks (the magnitudes A) with the same R₁ radicals for different groups of alkaloids has been shown for the spectra of the M⁺ and (M-15)⁺ ions. The reason for the quantitative differences of the B/E spectra of the (M-OH)⁺ ions from the spectra of the (M-OCH₃)⁺ and (M-OAc)⁺ ions, consisting in the influence of alternative methods of eliminating an OH radical, has been found. It has been confirmed that the values of A of analogous transitions calculated from the B/E and MD spectra are close to one another. On the other hand, the values of the energy of the metastable transitions obtained by these two methods differ from one another by two orders of magnitude.Institute of Chemistry of Plant Substances, Academy of Sciences of the Uzbek SSR, Tashkent. Special Design Bureau of Analytical Instrument Construction, Scientific and Technical Branch, Academy of Sciences of the USSR, Leningrad. Translated from Khimiya Prirodnykh Soedinenii, No. 1, pp. 72–84, January–February, 1991.     

Features of the splitting out of a methyl radical from lycoctonine alkaloids under electron impact

The mass spectra of 53 alkaloids and their derivatives are considered. It is known that the presence of a C₆(OCH₃)-C₇(OH)-C₈ (OH) grouping in C₁₉-diterpene alkaloids leads to a high intensity of the (M - 15)⁺ ions at the expense of the C₆(OCH₃) group and considerably suppresses the competing processes of forming the [M - OH (OCH₃)]⁺ ions in the alkaloids and the (M - 56)⁺ ions in the anhydroxy bases. When the above-mentioned grouping is absent, the (M - 15)⁺ ions are formed mainly by the splitting out of a ?H₃ from a N-ethyl group.     

Translational energy release and stereochemistry of steroids. XI—Determination of the configuration of α,β-unsaturated 3-keto steroid alcohols with the hydroxyl group in rings C and D

The elimination of water from metastable molecular ions of epimeric hydroxy steroids of the Δ⁴-3-keto series containing a hydroxyl group in the conformationally rigid rings C and D has been studied. The measurement of translational energy released during the loss of water and collision-induced decomposition (CID) mass-analysed ion kinetic energy (MIKE) spectrometry were the techniques used. It was found that it is possible to determine the configuration of the hydroxy steroids of this series on the basis of the CID MIKE spectra of [M ? H₂O]^+˙ ions formed by dehydration of metastable molecular ions in the first field-free region of a reversed geometry double-focusing mass spectrometer.     

Mass-analyzed ion kinetic energy spectra of the [M + 1]+ ions of aliphatic esters produced by chemical ionization

To test the similarity of chemical ionization (CI) spectra of esters to the collision-induced decomposition mass-analyzed ion kinetic energy (CID-MIKE) spectra of protonated esters, the CID-MIKE spectra of the [M + 1]⁺ ions of nineteen aliphatic esters were studied. The major fragments produced in the two kinds of experiment are similar, but there are significant differences in the ions of high mass, which would reduce the usefulness of library searches of CI spectra to identify MIKE spectra of [M + 1]⁺ ions.     

ToF‐SIMS and computation analysis: Fragmentation mechanisms of polystyrene,polystyrene‐d5, and polypentafluorostyrene

We studied the time‐of‐flight secondary ion mass spectrometry fragmentation mechanisms of polystyrenes—phenyl‐fluorinated polystyrene (5FPS), phenyl‐deuterated polystyrene (5DPS), and hydrogenated polystyrene (PS). From the positive ion spectra of 5FPS, we identified some characteristic molecular ion structures with isomeric geometries such as benzylic, benzocyclobutene, benzocyclopentene, cyclopentane, and tropylium systems. These structures were evaluated by the B3LYP‐D/jun‐cc‐pVDZ computation method. The intensities of the C₇H₂F₅⁺ (m/z = 181), CyPent‐C₉H₃F₄⁺ (m/z = 187), CyPent‐C₉H₄F₅⁺ (m/z = 207), and CyPent‐C₉H₂F₅⁺ (m/z = 205) ions were enhanced by resonance stabilization. The positive fluorinated ions from 5FPS tended to rearrange and produce fewer fluorine‐containing molecular ions through the loss of F (m/z = 19), CF (m/z = 31), and CF₂ (m/z = 50) ion fragments. Consequently, the fluorine‐containing polycyclic aromatic ions had much lower intensities than their hydrocarbon counterparts. We propose the fragmentation mechanisms for the formation of C₅H₅⁺, C₆H₅⁺, and C₇H₇⁺ ion fragments, substantiated with detailed analyses of the negative ion spectra. These ions were created through elimination of a pentafluoro‐phenyl anion (C₆F₅⁻) and H⁺, followed by a 1‐electron‐transfer process and then cyclization of the newly generated polyene with carbon‐carbon bond formation. The pendant groups with elements of different electronegativities exerted strong influences on the intensities and fragmentation processes of their corresponding ions.     

Dimer formation in methane chemical ionization mass spectrometry of organic functionalities,including 2-azaadamantane derivatives

The methane chemical ionization mass spectra of 1-hydroxy-2-azaadamantane, its lactolactam, and 1-chloro-2-azaadamantanes exhibit high intensity dimeric species. These correspond to [2M+H]⁺ or stable fragments formed via gas phase chemical reactions, such as dehydration (aminol case) or dehydrohalogenation (chloroazaadamantanes). The tert-amino chloroazaadamantane forms a stable [2M+C₂H₅]⁺ ion with much higher intensity than the [2M+H]⁺ ion. Similar dimeric species were observed with simple functionalities, including amide, amine, alcohol and alkene. Pressure, temperature and, apparently, steric effects play important roles. Structures are proposed for the various dimeric ions.     

Charge reversal of the enolate ions of acetaldehyde and acetone

Collisionally activated charge reversal of HCOCH₂^? and CH₃COCH₂^? produces positive ions whose fragments differ from those of other [C₂H₃O]⁺ ions formed by fragmentation of positive molecular ions, including the [C₂H₃O]⁺ ions from 2,2-dichlorethanol, considered formerly to have the HCOCH₂⁺ structure. The fragmentations of the charge reversed ions are concordant with the RCOCH₂⁺ structures. Least-squares correlations of the collisional activation spectra [C₂H₃O]⁺ are probed as a useful guide to claiming similarity or dissimilarity of ionic structure.     

Mass spectrometry of 3-substituted 4-hydroxyisoquinolines and their derivatives

Under electron impact, 3-aryl-4-hydroxyisoquinolines form [M – H]⁺, [M – CO]⁺ and [M – H – CO]⁺ ions with a subsequent elimination of HCN or CH₃CN. A cyclic structure for the [M – H]⁺ ion is suggested. The primary act of fragmentation of the corresponding methyle ether derivatives is the loss of CH₃?, as well as H?; the further fragmentatio is similar to that described above. It has been established that the unusual [M – H]⁺, [M – OH]⁺ and [M – CH₅?]⁺ ions are formed when 8 fragments. Fragmentation schemes for all compounds are proposed based upon high resolution mass spectra and deuterated analogues.     

Mass spectra of dihydroxy stereoisomers of 3-methoxy-1,3,5(10)-estratrienes

Electron impact mass spectral data for each of the four isomeric 16,17-, 15,17- and 14,17-diols of 3-methoxy-1,3,5(10)-estratriene and the 15,17-diols of 3-methoxy-14β-1,3,5(10)-estratriene are reported. The mass spectra of the diols show very similar fragmentation patterns except for differences in the relative abundances of particular ions. The different [M ? H₂O]⁺˙/[M] ⁺˙ and [M ? 2H₂O] ⁺˙ [M] ⁺˙ ratios can be used for distinguishing between the four isomeric 3-methoxy-1,3,5(10)-estratriene-14,17-diols as well as between the four isomeric 3-methoxy-14β-1,3,5(10)-estratriene-15,17-diols. No significant differences could be detected in the spectra of the epimeric 16,17-and 15,17-diols of 3-methoxy-1,3,5(10)-estratriene.     

Comparison of high- and low-energy collision-induced dissociation tandem mass spectrometry in the analysis of glycoalkaloids and their aglycons

Four aglycons (tomatidine, demissidine, solanidine, and solasodine) and three glycoalkaloids (α-tomatine, α-chaconine, and α-solanine) have been analyzed by positive ion liquid secondary ion high-energy and low-energy collision-induced dissociation (CID) tandem mass Spectrometry, performed on a four-sector (EBEB) and a hybrid (EBQQ) instrument, respectively. Both high- and low-energy collision-induced dissociation mass spectra of [M+H]⁺ ions of these compounds provided structural information that aided the characterization of the different aglycons and of the carbohydrate sequence and linkage sites in the glycoalkaloids. Low-energy CID favors charge-driven fragmentation of the aglycon rings, whilst high-energy CID spectra are more complex and contain additional ions that appear to result from charge-remote fragmentations, multiple cleavages, or complex charge-driven rearrangements. With respect to the structural characterization of the carbohydrate part, low-energy CID fragmentations of sugar residues in the glycoalkaloids generate Y _n ⁺ ions and some low intensity Z _n ⁺ ions; the high-energy spectra also exhibit strong ^1,5X _n ⁺ ions, formed by multiple cleavage of the sugar ring, and significant Z _n ⁺ ions.     

Where Does the Electron Go? Stable and Metastable Peptide Cation Radicals Formed by Electron Transfer

Electron transfer to doubly and triply charged heptapeptide ions containing polar residues Arg, Lys, and Asp in combination with nonpolar Gly, Ala, and Pro or Leu generates stable and metastable charge-reduced ions, (M + 2H)^+●, in addition to standard electron-transfer dissociation (ETD) fragment ions. The metastable (M + 2H)^+● ions spontaneously dissociate upon resonant ejection from the linear ion trap, giving irregularly shaped peaks with offset m/z values. The fractions of stable and metastable (M + 2H)^+● ions and their mass shifts depend on the presence of Pro-4 and Leu-4 residues in the peptides, with the Pro-4 sequences giving larger fractions of the stable ions while showing smaller mass shifts for the metastables. Conversion of the Asp and C-terminal carboxyl groups to methyl esters further lowers the charge-reduced ion stability. Collisional activation and photodissociation at 355 nm of mass-selected (M + 2H)^+● results in different dissociations that give sequence specific MS³ spectra. With a single exception of charge-reduced (LKGLADR + 2H)^+●, the MS³ spectra do not produce ETD sequence fragments of the c and z type. Hence, these (M + 2H)^+● ions are covalent radicals, not ion–molecule complexes, undergoing dramatically different dissociations in the ground and excited electronic states. The increased stability of the Pro-4 containing (M + 2H)^+● ions is attributed to radicals formed by opening of the Pro ring and undergoing further stabilization by hydrogen atom migrations. UV–VIS photodissociation action spectroscopy and time-dependent density functional theory calculations are used in a case in point study of the stable (LKGPADR + 2H)^+● ion produced by ETD. In contrast to singly-reduced peptide ions, doubly reduced (M + 3H)⁺ ions are stable only when formed from the Pro-4 precursors and show all characteristics of even electron ions regarding no photon absorption at 355 nm or ion-molecule reactions, and exhibiting proton driven collision induced dissociations.

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Graphical Abstract ?

     

Top‐down mass spectrometry of intact phosphorylated β‐casein: Correlation between the precursor charge state and internal fragments

Phosphorylated proteins play essential roles in many cellular processes, and identification and characterization of the relevant phosphoproteins can help to understand underlying mechanisms. Herein, we report a collision‐induced dissociation top‐down approach for characterizing phosphoproteins on a quadrupole time‐of‐flight mass spectrometer. β‐casein, a protein with two major isoforms and five phosphorylatable serine residues, was used as a model. Peaks corresponding to intact β‐casein ions with charged states up to 36⁺ were detected. Tandem mass spectrometry was performed on β‐casein ions of different charge states (12⁺, and 15⁺ to 28⁺) in order to determine the effects of charge state on dissociation of this protein. Most of the abundant fragments corresponded to y, b ions, and internal fragments caused by cleavage of the N‐terminal amide bond adjacent to proline residues (Xxx‐Pro). The abundance of internal fragments increased with the charge state of the protein precursor ion; these internal fragments predominantly arose from one or two Xxx‐Pro cleavage events and were difficult to accurately assign. The presence of abundant sodium adducts of β‐casein further complicated the spectra. Our results suggest that when interpreting top‐down mass spectra of phosphoproteins and other proteins, researchers should consider the potential formation of internal fragments and sodium adducts for reliable characterization.     

Ionic Fragmentation Mechanisms of 2,2,2‐Trifluoroethanol Following Excitation with Synchrotron Radiation

Gaseous 2,2,2‐trifluoroethanol (TFE) is excited with synchrotron radiation between 10 and 1000 eV and the ejected electrons and positive ions are detected in coincidence. In the valence‐electron energy region, the most abundant species is CH₂OH⁺. Other fragments, including ions produced by atomic rearrangements, are also detected; the most abundant are COH⁺, CFH₂⁺ and CF₂H₂⁺. The energies of electronic transitions from C 1 s, O 1 s and F 1 s orbitals to vacant molecular orbitals are determined. A site‐specific C 1 s excitation is observed. The photofragmentation mechanisms after the excitation of core‐shell electrons are inferred from analysis of the shape and slope of the coincidence between two charged fragments in the bi‐dimensional coincidence spectra. The spectra are dominated by islands that correspond to the coincidence of H⁺ with several charged fragments. One of the most important channels leads to the formation of CH₂OH⁺ and CF₃⁺ in a concerted mechanism.     

Mass Spectrometric Decomposition Processes in Labelled 1-Heptenes

The 70 eV mass spectra of a number of ¹³C- and D-labelled analogs of 1-heptene have been measured, as well as the metastable transitions in the non-labelled compound. Isotopic distributions in the major fragment ions have been calculated from the high and low resolution data. The results show that considerable skeletal rearrangement must take place before formation of most of the fragment ions. Loss of methyl and ethyl radicals occurs mainly from the two ends of the molecule. Ethylene fragments come primarily from the unsaturated end of the molecule, but show evidence of significant prior skeletal rearrangement. The predicted McLafferty rearrangement accounts for only 2/3 of the C₄H₈⁺ ions formed, less for the C₃H₆⁺ ions. At least 80% of C₄H₉⁺ ions appear to be formed by allylic cleavage, as expected, but this mechanism can only account for a maximum of 20% of the formation of the complementary ion C₃H₅⁺. Both, this latter ion and C₃H₆⁺, are probably generated by loss of hydrogen from C₃H₇⁺. Figures obtained for label retention in 1-[¹³C]- and 1-D-labelled analogs were nearly identical for most fragment ions, probably indicating that the hydrogen atoms in position 1 remain on C(1) even following skeletal rearrangement. A similar result was found for the 7-[¹³C]- and 7-D-labelled compounds. The main exceptions in the case of the products labelled in position 1 (C₄H₇⁺, C₃H₃⁺) seem to be due to initial loss of an hydrogen atom from this position followed by further fragmentation.